Pneumatic harvester

ABSTRACT

The pneumatic cotton harvesting apparatus includes a plurality of harvesting heads arranged in adjacent spaced relation side by side with each having a side panel opposing a side panel on an adjacent opposing harvesting head. An air intake manifold within each side panel has a plurality of extraction units with air intake ports for harvesting of seed cotton. The extraction units are each arranged in a staircase configuration to extract cotton into a pass-through chamber housed within the harvesting head. The cotton is transferred through the air plenum transfer chamber attached to the harvesting heads to a cotton storage container. Air supply nozzles arranged before the extraction units aid the extraction of cotton by blowing air on the cotton plant before entering the extraction units to loosen the cotton. Horizontal ledges above and below the air intake ports and raised deflectors forward and rearward of the of the air intake ports deflect the cotton plants away from the air intake ports and support the vacuum mechanism for extraction of the cotton seed through the extraction openings.

PRIORITY CLAIM

This application claims benefit of U.S. provisional application Ser. No. 61/216,882 filed on May 22, 2009.

FIELD OF THE INVENTION

The present invention relates to agricultural harvesters and particularly to an improved apparatus and method for pneumatic harvesting of cotton.

BACKGROUND OF INVENTION

Currently cotton harvesting is primarily accomplished by what may be characterized as a spindle picking device. Over the years, other methods have been tried including stripping devices and pneumatic harvesters. However, these methods have proved less effective than traditional spindle picking devices. Despite widespread adoption of spindle based harvesters, these spindle devices continue to have many disadvantages. For instance, spindle devices require a large number of spindles and moving parts such as drive gears, a lubrication system, bevel gears for each spindle, a doffer system for each horizontal row of spindles, and moistening plates. The spindle pickers use the rotating barbed spindles to snare seed cotton and pull it from the cotton plant. The doffers then remove the cotton from the spindles, and the cotton is blown into the harvester's basket. With increased harvesting speed, more spindles are required to keep pace with the speed of the harvester. The complex system of parts wears out and must remain in good repair to work correction because of their inter-dependence on each other for operation. Spindles can twist, warp or break. Further, the spindle devices can damage or wet the seed cotton, and the spindles cause trash content in the cotton from grinding bark from the cotton stalk. Safety is also a problem with spindle harvesters because the nature of rotating barbed spindles and the many moving parts.

Although pneumatic harvesters have been tried many times, no successful commercial harvester has been produced. Early cotton harvester inventors recognized the benefits of pneumatic harvesting, as International Harvester of Chicago, Ill. experimented with pneumatic pickers during the time that cotton was still being picked by hand. After several years of experiments the work was abandoned. Since then, much advancement has been made in harvesters and crop methods that have changed the landscape of cotton harvesting. The methods attempted by International Harvester early on did not reflect the modern crops and technology available today. Modern cotton crops are planted and grown closer together and in greater concentration, producing a more uniform cotton plant. Uniform growing of cotton plants makes it easier to compress cotton limbs together as cotton plants pass thru harvester units.

Modern cotton crops are well suited to a new method and device for pneumatic harvesting. Thus, a modern method and device are needed that take advantage of the manner in which a modern cotton crop will react well to air flow and easily dislodge cotton from the cotton burr. What is needed is a pneumatic harvester that does not have as many parts as a spindle device and will pick cotton more safely and effectively.

BRIEF SUMMARY OF THE INVENTION

The present invention provides an improved pneumatic cotton harvesting method using air flow (vacuum, atmospheric pressure) to harvest seed cotton. The invention overcomes the aforementioned problems with prior pneumatic cotton harvesters.

A pneumatic harvester has a header assembly comprising a main metal framework for attachment to the front lifting mechanism of a conventional self propelled cotton harvester's chassis for movement through a field of cotton plants in equally spaced rows. The header assembly includes an air plenum transfer chamber and harvester row units comprising harvesting heads. The harvesting heads contain opposing air intake manifolds, also referred to as opposing extraction panels. Each air intake manifold includes several self cleaning extractor units, usually four extractor units arranged in a staircase configuration on each manifold.

The air plenum transfer chamber has a top, sides, ends, and bottom as to form an airtight air plenum transfer chamber. The air plenum transfer chamber is mounted on top of the header assembly's main metal framework. The row units comprising harvesting heads are attached to the underside bottom area of the metal framework of the air plenum transfer chamber. The side panels of the harvesting heads are spaced apart approximately 9 inches apart with left and right side panels facing each other. The space between the harvesting heads creates a tunnel as to allow cotton plants to move thru the harvesting heads.

The self cleaning extractor units on the air intake manifold are attached to the harvesting heads in a 45° staircase configuration and are spaced in adjacent opposing relation on opposing air intake manifolds. The outermost face of the extractor units is approximately 5 inches apart from the opposing extractor unit. The staircase configuration promotes self cleaning as the extractor units begin harvesting cotton at the base of the cotton plants. The lower self cleaning extractor units are the first to come into contact with the cotton plants, and the self cleaning extraction openings are strategically placed to fully cover entire cotton plant. The 45° angle (step up staircase configuration) of harvester's self cleaning extractor units spreads the harvesting heads' contact over a larger number of cotton plants helping the extraction units to support each other as the harvesting heads push thru cotton plants. Further, the harvester's row unit's comprising each harvesting head has a smooth streamlined design that allows the harvester's row units to slide through cotton plants with the less resistance.

The pneumatic harvester uses air flow (vacuum, atmospheric pressure) to harvest seed cotton from cotton plants. The air flow is created by fans that force air from inside the air plenum transfer chamber, out thru the harvester's duct work to the harvester's basket on the harvester's chassis. As air is forced out it creates a vacuum inside the air plenum transfer chamber that causes the outside atmospheric pressure to force outside air in thru the harvester's air intake ports of the self cleaning extractor unit's openings. The intake air replaces the air that has been removed from (a) air plenum transfer chamber, thus creating a continuous air flow.

Cotton plants are compressed together to approximately 9 inches thickness between the harvesting heads as the harvester's row units enter the cotton row. The cotton plants are furthered compressed together to approximately 5 inches by the panels of the self cleaning extractor units, whereby the cotton plant's limbs are folded together in order to bring seed cotton into close contact with the self cleaning extractor units' extraction openings. Seed cotton is harvested from both sides of the cotton plants as air flow enters the harvesting heads from the front and rear and intensifies as it is forced thru the self cleaning extractor unit's openings. As air flow moves thru the cotton plants, the seed cotton is dislodged from the cotton bur and is then blown, rather vacuumed, into the self cleaning extractor unit's openings. The large amount of plant material moving thru the self cleaning extractor units creates a self cleaning environment using cotton plants to push unwanted material thru the harvesting heads.

In one embodiment of the invention, the air plenum chamber is divided into sections to allow for uneven field conditions, air turbulence and debris shields are used to cover flat surfaces to help restrict air turbulence and debris from collecting inside the air plenum transfer chamber to which the air supply is attached. The air plenum transfer chamber also serves to evenly regulate air flow to harvesting heads. Several side inspection panels are used for inspection and maintenance of the air plenum transfer chamber.

The harvesting heads have a left and right side panel with the front of panels sloping backward at a 45° angle, a front cover panel, a rear cover panel, and a bottom panel. Self cleaning extractor units attach to each of the harvester's side panels in a vertically stepped staircase configuration forming about a 45 degree upward angle on the air intake manifold. The front cover panels on the harvesting heads are designed to cover the open space between cotton rows which allows loose falling cotton to slide over onto pneumatic harvester's extraction units, whereby loose cotton that was lost previously by falling in-between cotton rows can be salvaged.

In an embodiment of the self cleaning extraction units, a bottom ledge, which also serves as top ledge, extends out from the side panel of the harvesting head approximately 2 inches. The extraction unit has an arrangement of mechanical features especially suited for moving cotton plants through the harvesting heads so that cotton is extracted and the remainder of the plants exit from the harvesting heads. These features for a separating arrangement that includes a front panel member on each extraction unit that extends outward approximately 2 inches and rearward at 45°, and a front flat panel situated about 2 inches from the side panel and parallel thereto. A rear flat panel is situated on the opposite side of the extraction opening and about 2 inches out from the side panel and parallel thereto. The rear flat panel terminates into a rear edge panel sloping rearward to harvester's side panel at 45°. The front flat panel and rear flat panel of the extraction units oppose adjacent front and rear flat panels on an opposing extraction unit. These panels provide a space of about 5 inches between them in a mode of practicing the invention as shown. The extraction unit openings angle forward 45° into the harvesting head side panel, which helps restrict plant material from becoming snared when passing the self-cleaning extractor opening 34.

Blower nozzles, which increase air flow, help dislodge hard locked seed cotton. The blower nozzles may oscillate or be stationary and can be arranged in different configurations. In the embodiment shown, the blower nozzles are located at on the harvesting head forward of the extraction unit openings. The blower nozzle blow streams of air against cotton bolls to help dislodge hard locked seed cotton prior to extraction by the air intake ports of the extraction units.

This spacing between the harvesting heads remains the same for wide row or narrow row cotton plant harvesting. An advantage of the invention is that the harvesting heads can be configured to harvest wide row cotton or narrow row cotton by repositioning cover panels and moving the harvesting heads' side panels closer together by an adapting set of cover panels that provide the air intake manifold. The air supply is run inside harvester's narrow row units, and the wide row header assembly's end row units are set up with air supply inside narrow row panel configuration.

It is an object of this invention to provide a pneumatic harvester header assembly with row units that can be configured to harvest wide row or narrow row cotton by repositioning the harvesting head panels.

It is another object of this invention to provide a more environmentally friendly pneumatic cotton harvester by eliminating the need for large amounts of lubricant and water that spindle harvesters require.

It is still another object of this invention to provide a less complicated cotton pneumatic harvester by completely eliminating the need for spindles, doffers, moistener pads, bars, chains, cutter blades, brushes, augers, and the many gears and miscellaneous parts now required on harvesters.

It is another object of this invention to provide a better quality of harvested seed cotton by eliminating wetting of seed cotton, seed damage, spindle twist, spindle warping, spindle breakage, bark grinding, and the high trash content of spindle and stripper harvesters.

It is another object of this invention to provide a much safer cotton pneumatic harvester by eliminating thousands of dangerous moving parts and cutter blades.

It is another object of this invention to reduce the large amount of seed cotton that falls to the ground which spindle harvesters are unable to harvest.

It is another object of this invention to provide a self cleaning pneumatic cotton harvester, by using the large amount of plant material constantly moving past harvester's self cleaning extractor units, thus creating a self cleaning environment using cotton plants to push unwanted material thru air harvester's row units.

It is another object of this invention to reduce the high manufacturing cost associated with new cotton harvesters by eliminating may of the moving parts now required on today's cotton harvesters. It is another object of this invention to reduce high maintenance and repair costs.

It is another object of this invention to provide a modern high volume cotton pneumatic harvester that is capable of harvesting the large amount of cotton required on modern cotton harvesters.

It is yet another object to the improve the weight and flexibility of pneumatic harvesters by allowing the harvester's row units to be grouped closer together than spindle harvesters or strippers.

Still another object of the invention is to provide a pneumatic cotton harvester with a harvesting head that can be arranged on row units that are mounted on tractors, ATVs, horse drawn wagons, or used as a single walk behind pneumatic harvester row unit.

These and other objects, features and advantages of the present invention will become apparent to one skilled in the art upon reading the following detailed description in view of the drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a front view of a wide row pneumatic cotton harvester header assembly, attached to the front of a conventional self propelled cotton harvester's chassis (prior art).

FIG. 2 shows a front view of a wide row pneumatic cotton harvester header assembly.

FIG. 3 is a side view of pneumatic cotton harvester's row unit.

FIG. 3A is a rear view of pneumatic cotton harvester's row unit's rear panel cover.

FIG. 4 is a front view of pneumatic cotton harvester's row unit.

FIG. 5 shows right side end view of pneumatic cotton harvester header assembly.

FIG. 6 shows front cut away view of pneumatic cotton harvester header assembly.

FIG. 7 is an enlarged view of FIG. 6 detailing air flow.

FIG. 8 is a top view of pneumatic cotton harvester's row units entering cotton row.

FIG. 9 is a side view enlargement of a self cleaning extractor unit showing seed cotton being extracted from cotton plant.

FIG. 10 is a side view of pneumatic cotton harvester's row unit entering cotton row.

FIG. 11 is a simplified front view of spindle type cotton harvester's row units moving thru cotton plants (prior art).

FIG. 12 is side view of spindle type cotton harvester's row unit FIG. 11 (prior art).

FIG. 13 shows front view of spindle type cotton harvester's row units (prior art).

FIG. 14 is a front view of pneumatic cotton harvester's row units showing front cover panels

FIG. 15 shows top and side views of harvester's self cleaning extractor unit.

FIG. 16 is a simplified schematic top view of pneumatic cotton harvester's row units.

FIG. 17 is a top view of pneumatic cotton harvester's row unit showing how air flow is used to harvest seed cotton from cotton plants.

FIG. 18 is a front view of wide row pneumatic cotton harvester header assembly.

FIG. 19 is a front view of narrow row pneumatic cotton harvester header assembly.

FIG. 20 is a front perspective view of a wide row pneumatic cotton harvester in accordance with an alternative embodiment of the invention.

FIG. 21 is a front perspective view of a pneumatic cotton harvester illustrating the manner of retrofitting from a modern spindle cotton harvester.

FIG. 22 is a front view of a section of pneumatic cotton harvesting heads illustrating conversion from a narrow row harvesting unit to a wide row harvesting unit.

FIG. 23 is a side cut-away view of the harvesting head for the present invention coupled to an air plenum.

FIG. 24 is a top cut-away view of an embodiment of the harvesting head.

FIG. 25 is a top cut-away view of a portion of an air transfer plenum chamber coupled to harvesting heads.

FIG. 26 is a side view of an alternative embodiment of the harvesting head coupled to an air plenum shown in cut-away view.

FIG. 27 is a front cut-away view of an embodiment of the harvesting head coupled to an air plenum illustrating transfer of cotton from the harvesting head to the air plenum transfer chamber.

DETAILED DESCRIPTION

The present invention provides a pneumatic cotton harvesting apparatus 2 using the modern method of harvesting row units comprising a plurality of harvesting heads 4, and the apparatus is capable of harvesting seed cotton from either wide row or narrow row planted cotton. FIGS. 18 and 19 illustrate configurations of the harvesting heads 4 of the pneumatic harvester for either wide row cotton plants or narrow row plants. The embodiments herein and the various features and advantageous details thereof are explained more fully with reference to the non-limiting embodiments that are illustrated in the accompanying drawings and detailed in the following description. The examples used herein are intended to facilitate an understanding of the ways in which the invention herein may be practiced and to further enable those skilled in the art to practice the embodiments herein. Accordingly, the examples should not be construed as limiting the scope of the claimed invention.

FIG. 1 and FIG. 20 illustrate a pneumatic cotton harvesting apparatus 2 in accordance with an embodiment of the present invention. As show in this front perspective view, the cotton harvesting apparatus 2 includes a modern self-propelled chassis 1A and conduit system 1C for storage of cotton in a storage container 1B that is carried on the apparatus. A wide row header assembly 6 is shown that attached to a front lifting mechanism on the harvester's chassis. The header assembly 6 is arranged for pneumatic removal of cotton from cotton plants and may be used in the wide row configuration shown in FIG. 1 or alternative configurations for different crop arrangement strategies such as the narrow row configuration shown in FIG. 19. The header assembly 6 may include several fans 8 connected to a conduit system for pneumatic transfer of cotton when picked. The fans 8 of the header assembly 6 may be adapted from an existing spindle based header assembly. The pneumatic header assembly 6 includes an arrangement of harvesting heads 4, as what is known as row units, which contain the pneumatic cotton extraction elements of the preferred embodiments.

The header assembly 6 includes an air plenum transfer chamber 10 having air plenum transfer chamber 12 on the front of the chamber as shown in FIG. 1. The shields cover the flat surfaces and the main metal framework of the chamber to reduce air turbulence, protect the interior elements of the header assembly 6, and reduce debris collecting inside an air plenum transfer chamber 10 located within the header assembly. The header assembly 6 and debris shields may include several service panels 14, as shown arranged on the front of the header assembly. These service panels 14 are arranged for inspection and maintenance of the header assembly 6 and the air plenum transfer chamber 10.

In general the pneumatic harvesting header assembly 6 includes several of the harvesting heads 4, the air plenum transfer chamber 10 and air vacuum source or fans 8 as shown in FIG. 2. The harvesting heads 4 are arranged side by side in spaced horizontal relation on the harvesting assembly as shown in FIG. 2 for movement through equally spaced rows of cotton plants, whereby the plants enter into the space between the harvesting heads. The harvesting heads 4 and harvesting assembly illustrated closely resembles a modern spindle picker in exterior appearance from a distance. However, the moving parts of a spindle picker as absent and the harvesting heads 4 include improved pneumatic features in the preferred embodiments for effective harvesting of cotton 18. As illustrated by FIGS. 18 and 19, the harvesting heads 4 may be arranged for wide or narrow rows according to the crop. Cotton 18 is harvested in the space between the harvesting heads 4 and is not harvested on the outside ends 20 of the outer harvesting heads. In one embodiment of the invention, the narrow row harvesting heads are converted to wide row harvesting heads using a conversion kit comprising a front cover wide row conversion panel 22 that connects two of the narrow harvesting heads and covers the space between them as show in FIG. 22 to eliminate the harvesting space in the area covered and seal the opening between the area covered.

The harvesting heads 4 are arranged in adjacent spaced relation side by side as shown in FIG. 2. Each harvesting head includes at least one side panel with an air intake manifold 26 providing an extraction panel as shown in FIG. 3. Further, each harvesting head 4 includes a rear cover panel 28 as shown in FIG. 3A, and a front cover panel 30 as shown in FIG. 4. The front cover panels 30 deflect cotton plants into or around the harvesting heads 4, and both front and rear cover panels keep debris out of the air plenum. The front cover panels 30 are arranged according to the crop rows to align the plants with the harvesting area between the harvesting heads 4. As shown in FIG. 14 and contrasted to the prior art in FIG. 13, the front cover panels are used to salvage loose cotton 18 before it can fall to the ground. Front cover panels cover the open space between rows of cotton plants and allows loose falling cotton 18 to slide over on the pneumatic harvester's extraction units 32. Loose cotton that was previously lost falling in between cotton rows can now be salvaged by the guiding of the plants into the area of the extraction units and the vacuum extraction of the extraction units. This is promoted by the ability to arrange the side panels 24 of the harvesting heads 4 more closely together.

The plants enter the harvesting heads 4 between a pair of panel sides or side panels 24 consisting of left and right side panels. The side panels 24 include an air intake manifold 26 as shown in FIG. 3 for extraction of cotton from both horizontal directions within the harvesting area between the harvesting heads 4, with the exception of the outside harvesting heads where the outside side panels 20 as shown in FIG. 5 do not include cotton extraction elements.

The air intake manifold 26 on the harvesting heads 4 includes extraction units 32 that are arranged on the left side panels and right side panels of each harvesting head, except the outside side panels 20 as discussed above. The extraction units 32 each include at least one extractor opening 34 comprising an air intake port 36 for harvesting of seed cotton within each of the extraction units.

The extractor openings 34 may include an opening with a lip 38 angled forward 45 degrees in the direction of the harvester's forward movement to help restrict plant material from becoming ensnared when passing the extractor opening, see FIGS. 15-17. The air intake ports 36 are each arranged with respect to the others as part of each of the extraction units 32, and the air intake ports pass through the side panel and connect to a pass-through chamber 40 housed within the harvesting head. In one embodiment, the extractor openings 34 and the air intake ports 36 are upwardly arranged one above the other within each extraction unit in a stair case configuration. Each air intake port 36 is spaced at least partially rearward of the one below to form a rearward diagonal line of the adjacent upper rearward and lower forward corners of the air intake ports, which line may be about 45 degrees on the air intake manifold 26. Thus, the air intake ports 36 are arranged in a staircase configuration from the front lower portion of the harvesting head toward the back upper portion of the harvesting head as shown in FIG. 10. This arrangement of the air intake ports 36 is believed to maximize efficiency as cotton 18 is removed from the stalk starting from the bottom of the cotton plants as the plants enter into the harvesting heads and the extraction units 32. The lower extraction units are the first to come into contact with cotton plants 16. The extraction units' openings are strategically placed to fully cover the entire cotton plant. Variations of the embodiment shown in FIG. 3 may include changes to the vertical alignment of the air intake ports or addition of air intake ports in selected rows or columns. For example, a second column of air intake ports may be arranged on the extraction units 32 on the left or right side panels 24.

The air intake ports 36 form the core feature of the extractor openings in the side panels 24 for extraction and passing through of cotton 18 into the pass-through chamber of the harvesting head where the cotton 18 is collected for transfer to the cotton storage container 1B through the air plenum transfer chamber 10. The air plenum transfer chamber 10 is made leak resistant and airtight for formation of a vacuum. The chamber includes a top, sides, ends, and bottom and provides the metal framework that the harvesting heads 4 are attached to. The bottom of the chamber may comprise a cap cover 42 shown in FIG. 23 that covers the pass-through chamber 40 of the harvesting heads 4. The air plenum transfer chamber 10 may be divided into sections of vent chambers having several vent caps 44 shown in FIG. 25 that accommodate uneven field conditions and improve the extraction vacuum effectiveness. On the inside of the air plenum transfer chamber 10, air plenum transfer chamber 12 cover flat surfaces. These shields restrict turbulence and prevent debris from collecting on the inside of the air plenum transfer chamber 10. The shields may be formed as an integral part of the top, sides, ends and bottom of the chamber's structure. Side inspection panels are provided in the ends of the air plenum transfer chamber 10 for inspection and maintenance of the chamber.

The air transfer plenum chamber connects to an air supply that is provided by a standard harvester fan. These are blower fans like those typically found on a harvesting machine and are mounted on the top of the air plenum transfer chamber 10 or can be mounted on the chassis. The blower fans provide a vacuum creation within the air plenum transfer chamber 10, which extracts cotton 18 from the plants through the air intake ports. Air exits the air plenum transfer chamber 10 and atmospheric pressure causes outside air to flow in thru the air intake ports, creating a continuous air flow as shown in FIG. 6. The enlarged view of FIG. 7 illustrates the air flow forcing the entry of outside air from directions including both front and rear to enter between the harvesting heads' 4 left and right side panels 24 through the air intake ports 36 of the extractor units. FIG. 17 illustrates the movement of cotton 18 through the harvesting head and the extraction units 32 in accordance with the air flow. As the air enters the air intake ports 36 the extraction openings of the extraction units 32 are self-cleaning to prevent entry of large unwanted matter, whereby only seed cotton 18 and minor small debris enters into the air plenum transfer chamber 10 as shown in FIG. 6.

FIG. 8 is a top view of the pneumatic harvester's harvesting heads 4 traversing a cotton row with cotton plants 16 entering into the space between the harvesting heads. The cotton plants 16 are compressed together to approximately 9 inches as the harvesting heads 4 enter the cotton row, and the plants are further compressed together to approximately 5 inches by the extractors units' opposing front deflectors 46 of the front panels. FIG. 16 is a top view showing the facing and spaced relationship of the extraction units 32 and deflectors. The cotton plants 16 limbs are folded together in order to bring the seed cotton 18 into close contact with the self-cleaning extractor units' openings, where seed cotton 18 is removed from the cotton plants 16. Cotton is harvested from both sides of the cotton plants 16 using vacuum air flow through the air intake ports. The large amount of plant material moving thru the extractor units creates a self-cleaning environment because of the configuration of features in the extractor units that causes the cotton plants 16 to push unwanted material thru the harvesting heads 4 past the extraction units 32′ openings.

Once extracted from the plants, the cotton 18 is transferred to the cotton storage container through a series of conduits that include the air plenum transfer chamber 10. The transfer path begins with the air intake ports 36 passing the cotton 18 through the harvesting head pass-through chamber 40 to the air plenum transfer chamber 10 and then through ducts 1C to the cotton storage container 1B. Cotton is a soft, fluffy, staple fiber that grows in a boll around the seeds of the cotton plant. Seed cotton refers to un-ginned picked cotton that is harvested from the plant and dislodged from the cotton bur, and this is what is stored in the cotton storage container. The seed cotton is removed from the plant leaving the cotton bur, which is the rough, prickly case around the seeds.

In a preferred embodiment the extraction units 32 include air supply nozzles 48 arranged forward of each of the extraction units toward a front end of the harvesting head where the cotton plants 16 enter. These air supply nozzles 48 may also be referred to as blower nozzles. These nozzles may be oscillating or stationary. The plurality of air supply nozzles 48 assist in removal of seed cotton from the bolls by loosening the cotton as the plants enter into the harvesting head area. The air supply nozzles 48 provide a positive flow of air that releases from the nozzles rearward into the harvesting head area toward the air intake ports. The plurality of nozzles increase air flow by directing air rearward with respect to the side panels to provide a rearward airflow to help dislodge hard locked seed cotton as shown in FIG. 9. The nozzles are arranged in coordination with the air intake ports 36 or in other manner to provide effective loosening of cotton. For example, the air supply nozzles 48 may be arranged vertically at a rearward sloping diagonal on the side panels in coordination with the air intake ports, with one nozzle for each port. Alternatively, additional nozzles may be arranged before the air intake ports 36 to loosen cotton in the areas around the air intake ports, whereby the extraction vacuum from the air intake ports can successfully extract the cotton from the bolls without direct contact. In this manner the air intake manifold 26 provides efficient extraction through the assistive manner in which the air supply nozzles 48 and air intake ports work together synergistically because of their stacked and offset relation.

Like all crops, cotton plants come with matter that is less desirable than the seed. Some of this matter lacks much in the way of usefulness or nutrients, such as the stalks and the burs. The present arrangement of features on the extraction units 32 enable to device to be self-cleaning as the extractor units move thru the cotton plants, while air flow dislodges and extracts seed cotton from cotton burs. A separating arrangement 50 is provided in accordance with an embodiment of the invention to prevent extraction of unwanted matter such as stalks and burs through the extraction units 32. A plurality of separating arrangements 50 is connected to the panel sides and each separating arrangement of the plurality integrates with one of the extraction units 32. The separating arrangement means arranged on the extraction units 32 for deflecting and moving the unwanted matter through the harvesting head, such that the unwanted matter does not snare and inhibit seed cotton from entering the air intake ports 36. The separating arrangement of the invention is arranged to avoid over-filtering of debris to prevent clogging, thus a debris filter could be included but is not preferred because of the potential for clogging. In particular, the separating arrangement includes a series of large open air intake ports 36 designed with mechanical features as discussed for effectively moving cotton plants 16 past the ports with the extraction of cotton. Any small loose debris present in the extraction openings is allowed to enter the air intake ports to prevent build up of debris and clogging of the extraction openings. Any debris in the seed cotton is removed during the ginning process. Large debris is separated by forming a mat between the extraction units 32 and is consistently pushed through the harvesting heads 4 by newly entering plants. It is an advantage of the present invention in that small vacuum nozzles prone to clogging that were used in prior pneumatic systems for suctioning cotton are not needed for effective extraction of cotton from plants in the present embodiments. It is understood, that the mechanical features can be manipulated to improve extraction of cotton and eliminate debris in the optimal manner through experimentation. In the context of this invention, separating arrangement concerns the movement of cotton plants 16 through the harvesting heads 4 with extraction and separation of cotton from the plants and minimal intake of unwanted matter into the air plenum transfer chamber 10.

In alternative embodiments as shown, the separating arrangement may operate through the arrangement of deflectors and angles of panels as shown in FIGS. 7-10, or may include several slider bars 52 arranged over each air intake port as shown in FIGS. 20-22 and FIGS. 24-26. The front end of the slider bars 52 are attached to the front edge of the air intake port 36 and large plant matter crossing the slider bars is prevented from entering the ports. Any large unwanted plant matter slides across the slider bars 52 or hangs and moves rearward on the bars as other matter pushes through the harvesting head. The rear end of the slider bars 52 is detached from the air intake ports as shown in FIG. 26, whereby any extra unwanted matter is allowed to escape from the air intake ports without hanging on the slider bars.

As the cotton plants 16 enter between the extraction units 32, the separating arrangement includes front deflectors 46 connected to the panel side as shown in FIGS. 15-17 arranged to move the plants away from the air intake ports 36 and permit the formation of a vacuum that reaches the cotton for extraction from the bolls. Each front deflector 46 may be arranged as part of the side panel or, alternatively, the front deflector may be arranged as an attachment to the extraction unit where a portion of the front deflector adjoins the air intake port 36. The front deflector 46 may have a front face member 54 that extends rearward and outward about 2 inches between the extraction units 32 at about a 45 degree angle to cause the cotton plants 16 to lift away from the side panel and the air intake ports a small amount. This movement of the cotton plants through compression into the center of the harvesting heads between the extraction units improves the extraction of cotton and helps minimize extraction of large unwanted matter. The front deflector 46 may include a flat surface member 56 extending rearward from the front face member 54 of the front deflector that directs the cotton plant rearward to the extraction unit opening. A rear face member 58 on the front deflector extends from the flat surface member 54 at an angle downward into the extractor opening and prevents any snagging of the cotton plants. The flat surface members 56 of the front deflectors 46 oppose like flat surface members on the opposing extraction unit and operate together to compress the plants into a narrower space between the flat surface members as discussed. The step-up angled configuration of the front deflectors 46 helps to spread the extraction units 32 contact over a larger number of cotton plants helping to support each other as the harvesting heads 4 push through the cotton plants 16.

As the cotton plants 16 exit the extraction units 32, the separating arrangement includes rear deflectors 60 shown in FIGS. 15-17 arranged to move the plants away from the air intake ports and permit the finishing of cotton extraction from that area of the plant. The rear deflectors 60 further prevent unwanted matter entering the air plenum transfer chamber 10 and help clear the air intake ports for further cotton extraction. Rear deflectors 60 extend from the rear edge of the air intake ports and begin with a front face member 62 that slopes outward toward the cotton plants and rearward into the harvester at an angle of about 45 degrees. The rear deflector may further include a flat surface member 64 extending rearward from the sloping front face member 62 of the rear deflector 60 and extends rearward further into the harvester. An additional rear face member 66 may extend from the flat surface member 64 in which the rear face member 66 provides an end shield that slopes rearward at an angle of about 45 degrees away from the cotton plants 16 to terminate at the side panel's surface to relieve the plants from the extraction units 32 and promote their progress through the harvester.

Each extraction unit 32 includes a pair of ledges 68 arranged particularly within respect to the air intake port of each extraction unit. Referring to FIGS. 9-10 and FIG. 26, a preferred arrangement of the ledges 68 will provide a first ledge that is arranged below each air intake port 36. The first ledge extends forward of the air intake port 36 above and extends to the rear of the air intake port above as far rearward as the rearward edge of the rear face member 66 of the rear deflector. The arrangement of the ledges 68 will also provide a second ledge that is above each air intake port 36. Note that the first ledge and second ledge may be the same for different air intake ports. The second ledge extends from the front edge of the air intake port 36 or the front deflector of the air intake port below, and the second ledge extends rearward to the rearward edge of the rear edge panel of the rear deflector of both air intake ports above and below. In an embodiment shown the first ledge and second ledge each extend out from the side panels 24 about 2 inches. This configuration of the ledge may be adjusted according to the side of the extraction units 32, experimental results for various crop configurations and various arrangements of the separating features or air intake ports. The smooth streamlined design of the separating arrangement for the extraction units 32 allows the harvesting heads 4 to slide through the cotton plants efficiently with the lease possible resistance.

The first and second ledges 68 help guide the cotton to the extractor units' openings and also promote loose falling cotton to be harvested before reaching the ground, unlike the wasted created by spindle type harvesters as shown in FIGS. 11-12. FIG. 11 is a simplified front view of a spindle type cotton harvester's row units showing loose cotton falling to the ground. Spindle type cotton harvesters are unable to harvest any cotton until cotton plants reach spindle units, which results in the loss of large amounts of loose cotton that falls to the ground. FIG. 12 is a side view of spindle type cotton harvester row units showing seed cotton falling to the ground unable to reach the spindle units. FIG. 13 is a front view of a spindle type cotton harvester row unit that also shows how these type harvesters require a large number of moving parts. These moving parts limit how close together harvester row units can be space and are further limited by the room needed for service and maintenance.

It will be understood that changes in the details, materials, steps and arrangements of parts that have been described and illustrated to explain the nature of the invention will occur to and may be made by those skilled in the art. Such modification may be made within the principles and scope of the invention without departing from the scope of the invention. Accordingly, the invention should be interpreted in accordance with the scope of the accompanying claims that intend to protect the invention broadly as well as in the specific form described. 

1) A cotton harvesting apparatus comprising a) harvesting heads arranged in adjacent spaced relation side by side; b) A panel side on each of the harvesting heads with each panel side opposing the panel side on the adjacent harvesting head; c) An air intake manifold on the panel side having a plurality of extraction units arranged on the panel side; d) Air intake ports for harvesting of seed cotton within each of the extraction units, the air intake ports are each arranged with respect to the others as part of each of the extraction units, and said air intake ports pass through the panel side and connect to a pass-through chamber housed within the harvesting head; e) an air plenum transfer chamber attached to the harvesting head and connected with the pass-through chamber and connected with an air supply attached to air plenum transfer chamber, said air supply creating an air intake vacuum with respect to each of the air intake ports; and f) a conduit for transfer of cotton between the air plenum transfer chamber and a cotton storage container. 2) A cotton harvesting apparatus as in claim 1 comprising a plurality of air supply nozzles on the panel side with said air supply nozzles arranged forward of each of said extraction units toward a front end of the harvesting head where cotton plants enter, said air supply nozzles directing air rearward with respect to the panel side for providing a rearward airflow toward the extraction units. 3) A cotton harvesting apparatus as in claim 1 in which a plurality of separating arrangements are connected to the panel side and each separating arrangement of the plurality integrates with one of the extraction units. 4) A cotton harvesting apparatus as in claim 3 in which the separating arrangements include a plurality of slider bars connected to the panel side at a forward end of the air intake port and said slider bars extend over the air intake port. 5) A cotton harvesting apparatus as in claim 4 in which the slider bars extend over the opening of the air intake port and include a terminal end that provides a gap between a terminal end of the slider bars and a rearward end of the air intake port. 6) A cotton harvesting apparatus as in claim 3 in which said separating arrangements include a front deflector connected to the panel side at a forward end of an opening of the air intake port and said front deflector extends outward from the panel side. 7) A cotton harvesting apparatus as in claim 6 in which the front deflector extends outward from the panel side at a 45 degree angle toward a rearward end of the air intake port. 8) A cotton harvesting apparatus as in claim 3 in which each of said extraction units includes a first ledge on the extraction unit, said first ledge being arranged below the air intake port and extending forward and rearward of the air intake port. 9) A cotton harvesting apparatus as in claim 8 in which each said extraction unit includes a second ledge, said second ledge being arranged above the air intake port and extending from a front edge of the air intake port and rearward of the air intake port, and said second ledge being the first ledge for any said extraction unit vertically situated above the second ledge on the panel side. 10) A cotton harvesting apparatus as in claim 3 in which said separating arrangements include a rear deflector arranged rearward of the air intake port within the extraction unit and the rear deflector extends outward and rearward from the air intake port at a 45 degree angle and terminates at a front edge of a flat panel on the extraction unit that is parallel to the panel side. 11) A cotton harvesting apparatus as in claim 10 in which said extraction unit includes an end shield extending from a rear edge of the flat panel at an angle and terminates at the panel side. 12) A cotton harvesting apparatus as in claim 1 in which said air intake ports are upwardly arranged one above the other in a staircase configuration with each spaced at least partially rearward of the one below. 13) A cotton harvesting apparatus as in claim 12 in which said air intake ports are aligned with each arranged rearward of the one below and aligned with adjacent upper rearward and lower forward corners of the air intake ports forming a linear line along an upward rearward angle of 45 degrees on the air intake manifold. 14) A cotton harvesting apparatus as in claim 1 in which said air supply consists of a fan attached above the air plenum transfer chamber. 15) A cotton harvesting apparatus as in claim 1 in which said plurality of harvesting heads include a combination of wide row front panels connecting pairs of the harvesting heads, blank air nozzle members, and blank port members for changing the width of the harvesting heads for changing the harvesting heads from narrow to wide rows for harvesting and said wide row panels, blank air nozzle members and blank port members being removable for changing the width of the harvesting heads from wide to narrow rows for harvesting. 16) A method for harvesting cotton comprising the steps of: a) directing cotton plants between a pair of adjacent harvesting heads; b) providing a plurality of air intake ports in a staircase configuration on a panel side of each harvesting head for removal of cotton seed; c) deflecting debris and cotton plants away from the air intake ports; d) supplying a flow of air inward through the air intake ports thereby creating a vacuum at the air intake ports; e) extracting the cotton seed from the cotton plant into the air intake ports and into a pass through chamber housed within the harvesting head; and f) transporting the cotton seed from the pass through chamber to a storage container via an air plenum transfer. 17) A method for harvesting cotton as in claim 16 including the additional step of blowing air on the cotton plant to remove debris from the plant and loosen the seed cotton from the plant as the plant prepares to pass the air intake ports. 18) A method for harvesting cotton as in claim 17 including the additional step of using horizontal panels above and below the air intake ports to deflect the cotton plants away from the air intake ports and support the vacuum for extraction of the cotton seed into the air intake ports. 19) A method for harvesting cotton as in claim 18 including the additional step of covering the air intake ports with a debris filter comprising several horizontal members to prevent debris from entering the air intake ports. 